DEP0002175DA - Transformer for toy trains - Google Patents

Description

The invention relates to an overcurrent-protected transformer for toys, in particular toy trains, and is intended to simply and reliably prevent the risk of fire and fatality that occurs in the event of overcurrents, particularly in the case of short circuits on the secondary side.

It is known to provide the necessary short-circuit security by means of circuit breakers which switch off the transformer at the given moment by means of an electromagnetic or thermal effect. However, this solution is unsatisfactory because it requires a special circuit breaker, which complicates the construction of the transformer and increases its production costs, and because the circuit breaker has to be returned to its initial position by hand after it has responded, which is often overlooked.

In addition, it has already been proposed to achieve short-circuit protection by deflecting the magnetic lines of force flowing into the secondary coil, by using a movable member of an overcurrent protection device acting as an armature to divert the magnetic flux or by causing a voltage drop in the secondary coil by moving the secondary coil against a braking force is produced. In both cases moving parts are required, which must be stored and controlled, which ones thus also making the construction of the transformer cumbersome.

It has now been found that the necessary overcurrent protection can surprisingly be guaranteed if an artificially increased force line spread is caused and an immovable magnetic shunt is assigned to the transformer for this purpose. As such, a completely or partially surrounding the iron core of the transformer, as a ring, bracket, bar or the like can be used. Shunt designed are used, the cross-section of which is so large and whose distance from the iron core is so small that an increased voltage drop occurs in the secondary coil, which excludes harmful heating. Since the voltage in the secondary coil when there is no load due to the then existing low scatter corresponds approximately to the turns ratio of the primary coil and secondary coil, but becomes greater with the load of the force line deflection, according to the invention, by choosing a magnetic shunt of suitable dimensions and the correct distance from the iron core, the in the event of a short circuit in the secondary coil, the voltage present in the secondary coil must be limited to the permissible level.

According to the invention, as the load increases, an automatically increasing voltage drop occurs in the secondary coil. The resulting loss of power in relation to the motor can on the one hand be readily accepted in view of the work required for toys and on the other hand has the advantage that the motor winding is also protected from thermal overload. It is particularly progressive that the invention enables overcurrent protection to be achieved without moving parts, so the transformer is characterized by its simplicity in terms of manufacturing technology. It is - This is another feature of the invention - it is even possible to avoid a special, fixed magnetic shunt by designing the support parts accommodating the iron core and / or the housing of the transformer as a shunt. Thus, according to the invention, the surprising progress can be made to make a toy transformer short-circuit-proof without additional devices or aids, merely with the aid of the components that are necessary anyway, namely iron core, coils, support parts and housing.

In a further development of the inventive concept, it is possible to use particularly sensitive devices such as rectifiers or the like. to secure against overload by generating an additional voltage drop in the secondary coil through a further or a reinforced shunt.

If the invention is applied to a tap-off transformer, that is, to a transformer with a fixed secondary coil, it is advisable to use a closed iron core with the primary coil on one leg and the secondary coil with adjustable voltage for the consumer on its opposite leg. If, in this case, a second secondary winding is to be provided for the operation of other consumers, e.g. for the operation of light bulbs, switches, etc. on toy trains, then some of the turns of the second secondary are on the same leg as the primary winding, the rest of the Windings, however, arranged on the same leg as the secondary coil. It can thereby be achieved that the voltage of the second secondary winding is not subject to the fluctuation that causes due to the short-circuit protection, the voltage of the first secondary coil is exposed.

When the invention is applied to a rotary transformer, the secondary coil with adjustable voltage is arranged on the rotary armature. On the free leg of the iron core, which is opposite the leg carrying the primary coil, a second secondary coil with non-regulated voltage can be provided for further loads.

The drawing illustrates the invention in some exemplary embodiments in a schematic representation. It shows

1 shows a tapping transformer with a secondary winding,

2 shows a tapping transformer with 2 secondary windings,

3 shows the design of a tapping transformer with supporting parts and housing as magnetic shunts,

4 shows a cross section,

5 shows a rotary transformer.

In the pick-off transformer according to FIG. 1, the magnetic core a carries the primary coil c on its leg b, which is connected to the mains, and on its leg d the secondary coil e, which can be switched to the consumer g via a tap changer f. The engine of the locomotive of a toy train, for example, may be considered as such.

A magnetic shunt h is assigned to the transformer, which in the illustrated embodiment is designed as a frame surrounding the magnetic core. The cross-section of this shunt and its distance i from the end faces of the iron core are dimensioned in such a way that a load-dependent voltage drop occurs in the secondary coil e as a result of the deflection of the lines of force, which limits the voltage in the secondary coil in the event of a short circuit to a harmless level. The distance of the frame h from the legs b and d of the iron core can be greater than the distance i.

In the tapping transformer according to FIG. 2, a frame-shaped magnetic shunt is also provided. However, this transformer has a second secondary winding for other consumers k, if it is a toy train, e.g. for the operation of incandescent lamps, switches and the like not to expose them to their fluctuations. Rather, the second secondary winding is arranged with part l (exp) 1 of its turns on leg d, with another part l (exp) 2 of its turns on leg b of iron core a. As such, the second secondary winding can be one with a voltage that cannot be regulated. However, it is also possible to make part l (exp) 1 of its turns controllable by means of suitable tapping.

The invention can of course be used for toy transformers, regardless of whether these AC or DC motors are connected upstream. In the latter case, as is the case in the exemplary embodiment according to FIG. 2, a rectifier m and a pole inverter n are connected between the secondary coil e and the consumer g. Since, for reasons of price, the rectifier column is usually designed so small that there is a risk of thermal overloading of the rectifier in spite of the short-circuit protection of the transformer, further application of the concept of the invention additionally increases the spread of the lines of force, which is already artificially increased to achieve the short-circuit protection of the transformer by installing another shunt or the one previously provided

Shunt is amplified to produce the desired additional voltage drop in the secondary coil. Such an increase in the load-dependent scatter can be achieved by reducing the distance i and increasing the cross section of the shunt k.

As FIGS. 3 and 5 show, a special frame-like, bracket-like or web-like shunt can be dispensed with if the supporting parts and / or the housing of the transformer are designed as a shunt for the purposes of the invention. In the embodiment according to FIGS. 3 and 4, two supports n (exp) 1 and n (exp) 2 are provided which accommodate the transformer by means of arms o which are pushed into the coils along the legs b and d. These supports, which are punched out of sheet metal in the form of strips, are tapped on the base plate q of the housing r by means of angled foot parts p. They serve as a magnetic shunt. As such, the housing r with its base plate q is also used, in that it is moved close enough to the supports n (exp) 1 and n (exp) 2, i.e. the iron core, and also has a cross-section that allows sufficient deflection of the lines of force. It is possible to cause the voltage drop required to protect the transformer against short circuits, for example through the carrier and the additional voltage drop to be generated to protect sensitive devices such as rectifiers and the like through the housing with the base plate.

In the case of small transformers, these protective measures are usually sufficient. In the case of transformers with greater power, an additional frame or the like may have to be used. according to Figures 1 and 2 are provided.

Based on the knowledge that the walls of the housing r due to the emerging magnetic leakage flux at the end faces of the transformer are subject to a strong alternating magnetic flux in the event of a short circuit, a further proposal according to the invention is to use the vibrating housing walls to emit an acoustic warning signal, which can be reinforced by a suitably designed tongue arranged on the housing wall. The invention thus leads to the progress that a short circuit or the like. immediately audible, so the cause of the short circuit can be eliminated quickly.

The rotary transformer, which is shown in Fig. 5, consists of the magnetic core s and the rotating armature t. The former carries the primary coil u connected to the network, the latter carries the secondary coil v with adjustable voltage for operating the consumer g.

The voltage drop in the secondary coil v given by the horns w of the magnetic core s is increased according to the invention by the frame-like magnetic shunt x in the manner explained several times, thus making the transformer short-circuit-proof.

A further secondary coil y with an unregulated voltage for operating further loads k can be arranged on the free leg of the iron core. In addition, what has been said about the tapping transformer explained above also applies in principle to the rotary transformer.

In this case, the secondary coil passes through the entire or almost the entire primary flux only at the highest secondary voltage. At lower voltages, the primary flux will more or less bypass the secondary coil. The voltage drop caused by the pole pieces, i.e. by the horns w, which increases with decreasing voltage, experiences a considerable increase due to the additional magnetic shunt. The voltage therefore changes more as the angle of rotation of the armature increases than with a transformer without an additional magnetic shunt. This results in a simplified regulation, since the armature does not have to be rotated as far to achieve a certain regulating effect. The regular work is thus reduced and handling is made easier.

In addition to the advantages already explained, the invention with regard to tapping transformers also has the advantage that the regulation becomes "softer". Since there is a specific voltage range between the various voltage levels, there is inherent abrupt regulation. As a result of the voltage drop produced according to the invention, which naturally becomes noticeable in every step, the transition from step to step becomes more fluid, and the regulation is consequently more finely stepped.

The invention is just as suitable for transformers for main current motors as it is for transformers for shunt motors. It can be used with particular advantage in motors with a magnetic field generated by permanent magnets, since such shunt motors are particularly vulnerable to thermal overload.

Claims (8)

1) Transformer for toys, especially toy trains, the overcurrent protection of which is carried out by deflecting the magnetic lines of force flowing into the secondary coil, characterized in that the transformer is assigned an immovable, load-dependent force line scattering causing magnetic shunt. 2) Transformer according to claim 1, characterized by a completely or partially surrounding the iron core, as a frame, bracket, web or the like. designed shunt whose cross-section is so large and whose distance from the end faces of the iron core is so small that there is an increased voltage drop in the secondary coil that excludes harmful heating. 3) Transformer according to claims 1 and 2, characterized in that to protect connected, particularly sensitive devices such as rectifiers and the like, an additional voltage drop can be generated in the secondary coil by a further or an increased shunt. 4) Transformer according to claims 1-3, characterized in that the support parts receiving the iron core and / or the housing of the transformer are designed as magnetic shunts. 5) Transformer according to claims 1-4, characterized in that the housing walls are designed as vibrating, acoustic display means and are optionally provided with sound-amplifying tongues. 6) tapping transformer according to claims 1-4, characterized in that a closed iron core carries the secondary coil with adjustable voltage for the consumer on one leg of the primary coil and on the opposite leg. 7) tapping transformer according to claim 6, characterized by a second secondary coil for further loads such that part of its turns on the same leg as the primary winding, the remaining part of its turns, however, is attached to the same leg as the secondary winding. 8) Rotary transformer according to claims 1-5, characterized in that in addition to the secondary coil located on the rotating armature with adjustable voltage for a consumer on the free leg of the iron core, a second secondary coil with unregulated voltage for other consumers is arranged.